Int J Curr Pharm Res, Vol 8, Issue 2, 52-60 Original Article
FORMULATION AND EVALUATION OF ANTIDEPRESSANT ORODISPERSIBLE TABLETS
P. SIREESHA*1, R. KIRANJYOTHI1
Department of pharmaceutics, Oil Technological Research Institute, Anantapuram, A. P 515001
Email: sireesha.panditha@gmail.com
Received: 25 Jan 2016, Revised and Accepted: 20 Mar 2016
ABSTRACT
Objective: Orodispersible tablet formulation was proposed to be developed for fluoxetine hydrochloride taking into consideration it’s physical, chemical, pharmacological and pharmacokinetic properties and was proposed to be investigated with respect to its potential to be developed into novel drug delivery system
Methods: Carrying out pre-formulation studies such as drug-polymer interaction analysis by Fourier Transform Infrared (FTIR) spectroscopy and pre-compression characterization of a physical mixture of drug and excipients. Preparation of the orodispersible tablet by using various super disintegrants like croscarmellose, crospovidone & sodium starch glycolate. Preparation of the orodispersible tablet by using various methods like wet granulation method & sublimation method.
Results: To evaluate tablets for various physicochemical parameters such as hardness, friability, weight variation, drug content, wetting time, in vitro disintegration time, in vitro dissolution.
Conclusion: Finally concluded that the oro dispersible tablet of fluoxetine hydrochloride formulated by sublimation method by using crospovidone at 4.5% level used for depression treatment.
Keywords: Fluxetine, orodispersible tablets, Crosscarmellose, Crospovidone, Sodium starch glycolate
© 2016 The Authors. Published by Innovare Academic Sciences Pvt Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)
INTRODUCTION
The performance of ODTs depends on the technology used in their manufacture. The orally disintegrating property of these tablets is attributable to the quick ingress of water into the tablet matrix, which creates porous structure and results in rapid disintegration [1, 2]. Hence, the basic approaches to develop ODTs include maximizing the porous structure of the tablet matrix, incorporating the appropriate disintegrating agent and using highly water-soluble excipients in the formulation. Fluoxetine hydrochloride is the first agent of the class of antidepressants known as selective serotonin-reuptake inhibitors (SSRIs) [3]. Despite distinct structural differences between compounds in this class, SSRIs possess similar pharmacological activity.
MATERIALS AND METHODS
Materials
Fluoxetine, lactose, starch, aspartame, magnesium trisilicate, talc cross carmellose, crospovidone & sodium starch glycolate
Methods
For the following study, we are Taken captopril. Fluoxetine hydrochloride is the first agent of the class of antidepressants known as selective serotonin-reuptake inhibitors (SSRIs) [5-7]. In this study first, we did preformulation study.
In this preformulation study, we studied about the API characterization of drug, Drug-Excipient compatibility studies, Analytical method development, and Precompression parameters.
API characterization
It is necessary to study the physicochemical properties of the bulk drug-like physical appearance, solubility, melting point, particle size, and incompatibilities [4].
Analytical method development
It is studied for knowing about the purity of the drug. It is carried out by two methods HPLC or U. V. Here we have followed U. V method [9, 10]. Then we went for the formulation development.
Formulation development and evaluation
For this study, we developed 9 formulations in different ratio. The following table is shown formulation development for the present study.
Table 1: Formulation composition of orodispersible tablet of fluoxetine hydrochloride for wet granulation method
| Ingredients | FW1 (mg) |
FW2 (mg) |
FW3 (mg) |
FW4 (mg) |
FW5 (mg) |
FW6 (mg) |
FW7 (mg) |
FW8 (mg) |
FW9 (mg) |
| Drug(Fluoxetine) | 10 | 10 | 10 | 10 | 10 | 10 | 10 | 10 | 10 |
| Lactose | 59.5 | 58 | 56.5 | 59.5 | 58 | 56.5 | 59.5 | 58 | 56.5 |
| Starch | 20 | 20 | 20 | 20 | 20 | 20 | 20 | 20 | 20 |
| Cross carmellose | 1.5 | 3 | 4.5 | - | - | - | - | - | - |
| Crospovidone | - | - | - | 1.5 | 3 | 4.5 | - | - | - |
| Sodium starch glycolate | - | - | - | - | - | - | 1.5 | 3 | 4.5 |
| Poly vinyl pyrolidine | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 |
| Aspartame | 3 | 3 | 3 | 3 | 3 | 3 | 3 | 3 | 3 |
| Magnesium stearate | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 |
| Talc | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 |
Table: 2 Formulation composition of orodispersible tablet of fluoxetine hydrochloride for sublimation method
| Ingredients | FS1 (mg) | FS2 (mg) |
FS3 (mg) |
FS4 (mg) |
FS5 (mg) |
FS6 (mg) |
FS7 (mg) |
FS8 (mg) |
FS9 (mg) |
| Drug(Fluoxetine) | 10 | 10 | 10 | 10 | 10 | 10 | 10 | 10 | 10 |
| Lactose | 54.5 | 53 | 51.5 | 54.5 | 53 | 51.5 | 54.5 | 53 | 51.5 |
| Starch | 20 | 20 | 20 | 20 | 20 | 20 | 20 | 20 | 20 |
| Camphor | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 |
| Cross carmellose | 1.5 | 3 | 4.5 | - | - | - | - | - | - |
| Crospovidone | - | - | - | 1.5 | 3 | 4.5 | - | - | - |
| Sodium starch glycolate | - | - | - | - | - | - | 1.5 | 3 | 4.5 |
| Poly vinyl pyrollidine | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 |
| Aspartame | 3 | 3 | 3 | 3 | 3 | 3 | 3 | 3 | 3 |
| Magnesium stearate | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 |
| Talc | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 |
RESULTS AND DISCUSSION
Standard graph of Fluoxetine hydrochloride in 0.1N HCl
Table: 3 Data of the standard calibration curve of fluoxetine hydrochloride, Medium 0.1N HCl; λmax=226 nm
| Concentration (µg/ml) | Absorbance at 226 nm |
| 0 | 0 |
| 2 | 0.066 |
| 4 | 0.186 |
| 6 | 0.242 |
| 8 | 0.333 |
| 10 | 0.418 |
| 12 | 0.505 |
| 14 | 0.582 |
| 16 | 0.669 |
| 18 | 0.757 |
| 20 | 0.836 |
Fig. 1: Standard graph of fluoxetine hydrochloride. Medium 0.1N HCl; λmax=226 nm
Preformulation studies
Fourier transforms infrared spectroscopy (FTIR)
Table 4: Observed frequencies in the FTIR spectra of pure drug (fluoxetine hydrochloride) and physical mixture with their assignments
| Frequency observed in IR spectrum (cm-1) | Assignments |
3440.7 1070.1 |
Amines stretching vibration (N-H) (N-C) stretching |
| 2960.3 | Alkane (C-H stretching) |
3014.5 1518.2 |
Aromatic (C-H stretching) (C=C stretching) |
| 1242 | Phenoxy stretching vibration (C-O-Aromatic group) |
| 1331 | Halide stretching vibration (C-F) |
1108 1050 842 699 588 526 |
Fingerprint absorption bands |
Powder characterization
The powder mixtures of different formulations were evaluated for angle of repose, Hausner ratio, and compressibility index and their values were shown in (table 6, 3).
Evaluation of tablets
The Oro dispersible tablets of different formulations were evaluated for Weight variation, Hardness, Thickness, Friability test, Drug content and their values were shown in (table 6, 4).
Fig. 2: FTIR spectra of fluoxetine hydrochloride. (Pure drug)
Fig. 3: FTIR spectra of physical mixture containing drug and Cross carmellose
Fig. 4: FTIR spectra of physical mixture containing drug and Cross povidone
Fig. 5: FTIR spectra of physical mixture containing drug and Sodium starch glycolate
Fig. 6: FTIR spectra of physical mixture containing drug and starch
Fig. 7: FTIR spectra of physical mixture containing drug and PVP
Fig. 8: FTIR spectra of physical mixture containing drug and lactose
Fig. 9: FTIR spectra of drug formulation
Table 5: Flow properties of the final powder blend
| Formula code | Bulk density (gm/cm3) |
Tapped density(gm/cm3) | Carss index (%) |
Angle of repose | Hausners ratio |
| FW1 | 0.341±0.04 | 0.422±0.04 | 12.46±1.87 | 27 °.11΄±0.065 | 1.14±0.01 |
| FW2 | 0.357±0.03 | 0.423±0.06 | 9.50±1.23 | 26 °.12΄±0.043 | 1.10±0.03 |
| FW3 | 0.365±0.12 | 0.405±0.06 | 12.75±1.98 | 28 °.21΄±0.032 | 1.14±0.01 |
| FW4 | 0.333±0.32 | 0.403±0.02 | 11.11±0.05 | 28 °.32΄±0.05 | 1.12±0.03 |
| FW5 | 0.371±0.05 | 0.417±0.05 | 13.08±0.42 | 27 °.09΄±0.06 | 1.15±0.02 |
| FW6 | 0.370±0.06 | 0.467±0.09 | 12.69±0.05 | 29 °.12΄±0.03 | 1.15±0.03 |
| FW7 | 0.364±0.06 | 0.467±0.16 | 10.61±0.76 | 27 °.34΄±0.07 | 1.14±0.06 |
| FW8 | 0.369±0.09 | 0.428±0.14 | 10.73±0.32 | 30 °.20΄±0.04 | 1.11±0.02 |
| FW9 | 0.375±0.05 | 0.408±0.31 | 12.55±0.64 | 26 °.10΄±0.08 | 1.12±0.03 |
| FS1 | 0.378±0.01 | 0.403±0.87 | 11.21±0.46 | 27 °.22΄±0.03 | 1.14±0.05 |
| FS2 | 0.339±0.07 | 0.402±0.54 | 11.81±0.97 | 27 °.31΄±0.03 | 1.17±0.06 |
| FS3 | 0.357±0.12 | 0.413±0.07 | 12.09±0.97 | 28 °.08΄±0.07 | 1.13±0.03 |
| FS4 | 0.378±0.14 | 0.427±0.34 | 9.95±0.13 | 29 °.32΄±0.07 | 1.12±0.02 |
| FS5 | 0.369±0.15 | 0.431±0.24 | 11.13±0.1 | 31 °.41΄±0.08 | 1.08±0.01 |
| FS6 | 0.381±0.21 | 0.418±0.65 | 11.28±1.09 | 29 °.28΄±0.09 | 1.12±0.02 |
| FS7 | 0.384±0.06 | 0.422±0.06 | 11.57±1.65 | 28 °.21΄±0.04 | 1.21±0.05 |
| FS8 | 0.344±0.25 | 0.413±0.07 | 11.75±0.05 | 29 °.08΄±0.03 | 1.32±0.02 |
| FS9 | 0.362±0.14 | 0.395±0.03 | 12.53±0.06 | 27 °.11΄±0.05 | 1.14±0.05 |
Data represents mean±SD (n=3)
Table 6: Physical evaluation parameters of orodispersible tablets
| Formula code | Weight variation(mg) | Hardness (Kg/cm2) | Thickness (mm) | Friability (%) | Drug content (%) |
| FW1 | 99.4±0.6 | 3.1±0.1 | 2.20±0.01 | 0.41±0.03 | 95.9±0.07 |
| FW2 | 98.9±0.81 | 3.2±0.12 | 2.22±0.03 | 0.57±0.04 | 98.6±0.06 |
| FW3 | 100.05±0.85 | 3.3±0.15 | 2.23±0.035 | 0.47±0.02 | 98.1±0.05 |
| FW4 | 99.6±0.37 | 3.1±0.13 | 2.12±0.03 | 0.34±0.035 | 97.6±0.02 |
| FW5 | 100.3±0.53 | 3.2±0.14 | 2.20±0.015 | 0.42±0.03 | 97.8±0.07 |
| FW6 | 99.5±0.97 | 3.4±0.1 | 2.11±0.03 | 0.35±0.015 | 99.1±0.02 |
| FW7 | 100.3±0.88 | 3.2±0.17 | 2.28±0.035 | 0.46±0.034 | 95.4±0.04 |
| FW8 | 99.7±0.51 | 3.1±0.1 | 2.30±0.03 | 0.57±0.015 | 96.4±0.05 |
| FW9 | 98.8±0.88 | 3.2±0.15 | 2.29±0.04 | 0.66±0.026 | 97.1±0.052 |
| FS1 | 99.5±1.08 | 2.5±0.21 | 2.34±0.052 | 0.62±0.04 | 96.4±0.041 |
| FS2 | 100.4±0.65 | 2.7±0.16 | 2.37±0.05 | 0.59±0.05 | 98.6±0.039 |
| FS3 | 100.7±1.07 | 3.0±0.1 | 2.49±0.05 | 0.55±0.03 | 97.1±0.05 |
| FS4 | 98.8±1.23 | 2.8±0.2 | 2.25±0.036 | 0.5±0.026 | 99.1±0.045 |
| FS5 | 99.2±0.19 | 2.7±0.21 | 2.31±0.03 | 0.54±0.03 | 98.1±0.061 |
| FS6 | 98.7±0.89 | 3.1±0.32 | 2.24±0.07 | 0.44±0.032 | 98.3±0.042 |
| FS7 | 100.3±1.21 | 2.7±0.08 | 2.45±0.06 | 0.61±0.03 | 96.9±0.061 |
| FS8 | 98.01±1.46 | 2.8±0.16 | 2.51±0.03 | 0.65±0.04 | 97.6±0.04 |
| FS9 | 100.3±0.78 | 2.7±0.17 | 2.49±0.04 | 0.61±0.031 | 97.8±0.05 |
Data represents mean±SD (n=3)
Disintegration time
The Orodispersible tablets of disintegration time were evaluated, and their values were shown in (table.6.5. and in fig. 6.10).
Table 7: Disintegration times of orodispersible tablets
| Formula code | Disintegration time (sec) |
| FW1 | 86±4.35 |
| FW2 | 76±2.51 |
| FW3 | 72±1.5 |
| FW4 | 75±1.4 |
| FW5 | 43±1.15 |
| FW6 | 35±3.6 |
| FW7 | 106±4.09 |
| FW8 | 97±3.6 |
| FW9 | 86±3.65 |
| FS1 | 64±4.5 |
| FS2 | 45±2.51 |
| FS3 | 41±2 |
| FS4 | 25±3.05 |
| FS5 | 20±1.08 |
| FS6 | 13±1.5 |
| FS7 | 86±3.7 |
| FS8 | 74±4.3 |
| FS9 | 65±3.6 |
Data represents mean±SD (n=3)
Fig. 10: Disintegration time profile of orodispersible tablets
Wetting time
Wetting time of dosage form is related to the contact angle. The Orodispersible tablets of disintegration time were evaluated, and their values were shown in (table.6.6. and in fig. 6.11 and 6.12).
Table 8: Wetting time of orodispersible tablets
| Formula code | Wetting time (sec) |
| FW1 | 82±2.3 |
| FW2 | 71±3.1 |
| FW3 | 65±2.45 |
| FW4 | 59±3.54 |
| FW5 | 38±4.12 |
| FW6 | 30±1.23 |
| FW7 | 94±5.2 |
| FW8 | 89±3.21 |
| FW9 | 80±1.8 |
| FS1 | 51±1.32 |
| FS2 | 40±1.42 |
| FS3 | 37±1.23 |
| FS4 | 23±1.54 |
| FS5 | 16±2.32 |
| FS6 | 10±1.23 |
| FS7 | 75±1.24 |
| FS8 | 65±1.45 |
| FS9 | 54±2.34 |
Data represents mean±SD (n=3)
Fig. 11: Wetting time profile of orodispersible tablets
| Before wetting | After wetting |
Fig. 12: Photograph of wetting of oro dispersible tablets
In vitro dissolution studies
Table 9: Cumulative percent drug release of formulation with cross carmellose as super disintegrant. Medium= 0.1N HCl, λmax=226 nm
| Time(min) | FW1 | FW2 | FW3 |
| 5 | 51.5±0.87 | 53.3±0.98 | 57.1±0.57 |
| 10 | 58.3±0.77 | 60.3±1.04 | 64.5±0.98 |
| 15 | 67.2±0.98 | 71.4±0.82 | 72.3±0.67 |
| 20 | 73.4±1.07 | 76.3±1.18 | 79.3±1.67 |
| 30 | 79.3±0.89 | 81.3±0.87 | 85.9±1.34 |
| 45 | 82.3±1.06 | 84.3±0.73 | 88.5±0.98 |
| 60 | 85.2±0.75 | 87.5±0.65 | 91.5±0.85 |
Data represents mean±SD (n=3)
Fig. 13: Cumulative % drug release of orodispersible tablets incorporated with cross carmellose Vs Time, Medium= 0.1N HCl, λmax=226 nm
Fig. 14: Cumulative % drug release of orodispersible tablets incorporated with Crospovidone Vs Time, Medium= 0.1N HCl, λmax=226 nm
Table 10: Cumulative percent drug releases of formulations with Crospovidone as super disintegrant. Medium= 0.1N HCl, λmax=226 nm
| Time(min) | FW4 | FW5 | FW6 |
| 5 | 58.1±0.87 | 63.2±0.97 | 67.5±0.87 |
| 10 | 64.4±0.93 | 69.7±1.38 | 72.3±0.53 |
| 15 | 70.5±0.65 | 74.7±0.67 | 79.6±1.25 |
| 20 | 74.5±0.98 | 79.4±1.67 | 84.5±0.76 |
| 30 | 78.3±1.07 | 86.8±0.65 | 92.3±1.38 |
| 45 | 82.1±0.89 | 92.3±0.98 | 99.4±0.67 |
| 60 | 87.3±1.46 | 97.5±0.77 | - |
Data represents mean±SD (n=3)
Table 11: Cumulative percent drug releases of formulations with sodium starch glycolate as super disintegrant. Medium= 0.1N HCl, λmax=226 nm
| Time (min) | FW7 | FW8 | FW9 |
| 5 | 50.8±0.97 | 52.5±1.53 | 56.3±1.65 |
| 10 | 57.3±0.87 | 59.5±0.65 | 62.8±0.98 |
| 15 | 65.5±1.03 | 68.3±0.97 | 71.4±0.47 |
| 20 | 71.6±0.63 | 75.8±0.76 | 78.3±1.42 |
| 30 | 77.4±0.99 | 80.3±1.45 | 82.6±0.95 |
| 45 | 80.6±1.42 | 83.1±0.63 | 85.9±0.86 |
| 60 | 83.4±0.86 | 86.8±0.99 | 90.4±1.45 |
Data represents mean±SD (n=3)
Table 12: Cumulative percent drug releases of formulations with Cross carmellose as super disintegrant, Medium= 0.1N HCl, λmax=226 nm
| Time (min) | FS1 | FS2 | FS3 |
| 5 | 60.3±0.43 | 64.3±0.64 | 67.5±0.83 |
| 10 | 68.6±0.93 | 70.9±0.46 | 71.7±0.93 |
| 15 | 73.6±1.36 | 76.3±0.82 | 78.3±0.78 |
| 20 | 78.4±0.75 | 80.2±0.93 | 85.9±0.63 |
| 30 | 81.3±0.78 | 85.6±0.62 | 91.3±1.26 |
| 45 | 87.5±0.86 | 92.4±0.87 | 99.3±0.73 |
| 60 | 94.1±0.93 | 99.1±1.07 | - |
Data represents mean±SD (n=3)
Fig. 15: Cumulative % drug release of orodispersible tablets incorporated with sodium starch glycolate Vs Time, Medium= 0.1N HCl, λmax=226 nm
The oro dispersible tablets prepared by sublimation method FS-1 to FS-9 by using super disintegrates were evaluated for in vitro drug release behavior, and the results of the formulations were expressed in (tables 6.10-6.12).
Fig. 16: Cumulative % drug release of orodispersible tablets incorporated with cross-carmellose Vs Time, Medium= 0.1N HCl, λmax=226 nm
Table 13: Cumulative percent drug releases of formulations with Cross povidone as super disintegrant, Medium= 0.1N HCl, λmax=226 nm
| Time (min) | FS4 | FS5 | FS6 |
| 5 | 69.8±0.88 | 72.3±0.72 | 78.9±0.91 |
| 10 | 75.7±0.93 | 80.3±0.67 | 89.3±0.85 |
| 15 | 78.6±0.76 | 88.7±0.94 | 99.5±0.95 |
| 20 | 81.3±0.83 | 95.4±0.76 | - |
| 30 | 88.6±0.67 | 98.9±1.12 | - |
| 45 | 92.4±1.04 | - | - |
| 60 | 99.3±0.95 | - | - |
Data represents mean±SD (n=3)
Table 14: Cumulative percent drug releases of formulations with sodium starch glycolate as super disintegrant, Medium= 0.1N HCl, λmax=226 nm
| Time (min) | FS7 | FS8 | FS9 |
| 5 | 59.8±0.96 | 61.4±1.07 | 65.3±0.84 |
| 10 | 65.8±0.45 | 67.3±0.87 | 70.4±0.73 |
| 15 | 71.9±1.13 | 74.8±0.97 | 78.3±0.67 |
| 20 | 77.6±0.99 | 78.8±0.87 | 83.2±0.68 |
| 30 | 80.4±0.82 | 84.9±0.73 | 90.5±0.56 |
| 45 | 85.3±0.95 | 90.3±0.75 | 98.9±0.86 |
| 60 | 92.5±0.86 | 96.3±0.98 | - |
Data represents mean±SD (n=3)
Fig. 17: Cumulative % drug release of orodispersible tablets incorporated with Cross povidone Vs Time, Medium= 0.1N HCl, λmax=226 nm
Fig. 18: Cumulative % drug release of orodispersible tablets incorporated with sodium starch glycolate Vs Time, Medium= 0.1N HCl, λmax=226 nm
Fig. 19: Comparison of cumulative % drug release of oro dispersible tablets incorporated with Cross povidone Vs Time, Medium= 0.1N HCl, λmax=226 nm
Model fitting data for drug release
Table 15: Kinetic model fitting data for all the formulations prepared by wet granulation method
| Batch | Zero order | First order |
| FW1 | 0.820 | 0.913 |
| FW 2 | 0.794 | 0.913 |
| FW 3 | 0.823 | 0.941 |
| FW 4 | 0.894 | 0.971 |
| FW 5 | 0.938 | 0.984 |
| FW 6 | 0.958 | 0.986 |
| FW 7 | 0.831 | 0.918 |
| FW 8 | 0.811 | 0.917 |
| FW 9 | 0.838 | 0.952 |
Table 16: Kinetic model fitting data for all the formulations prepared by sublimation method
| Batch | Zero order | First order |
| FS1 | 0.921 | 0.976 |
| FS2 | 0.956 | 0.997 |
| FS 3 | 0.951 | 0.981 |
| FS 4 | 0.964 | 0.989 |
| FS5 | 0.910 | 0.982 |
| FS6 | 0.991 | 0.998 |
| FS7 | 0.918 | 0.972 |
| FS 8 | 0.926 | 0.974 |
| FS 9 | 0.961 | 0.931 |
CONCLUSION
Oro dispersible tablet of fluoxetine hydrochloride prepared using various concentrations (1.5%, 3% & 4.5%) of super disintegrates like crosscarmellose, crospovidone, sodium starch glycolate by wet granulation method & sublimation method. The preformulation studies by FTIR confirmed no interactions between drug and polymers. The prepared formulations were evaluated for the pre-compression parameters & the values were within prescribed limits and indicated good free flowing properties. The physical parameters were found satisfactory & within the limits. Upon comparison sublimation method was showed good results for disintegration time, wetting time & in vitro drug release studies because sublimation of camphor to increase the porosity of the tablets. The tablets prepared with crospovidone at 4.5% concentration (FS-6) by sublimation method was found to be best formulation as it exhibited satisfactory physical parameters, least disintegration time (13 sec.),wetting time (10 sec.) & highest % drug release (99.5%) in 15 min. The drug release pattern from the optimized formulations was best fitted to first-order kinetics.
AKNOWLDGEMENT
We would like to thank our Director sir and other teaching and nonteaching faculty who help to carry out this research in the institution.
CONFLICT OF INTERESTS
Declare none
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